Experimental Study of Dry Aerosol Jet Printing with Sheath Gas-assisted Aerodynamics Lens Focusing

doi:10.3969/j.issn.1004-132X.2024.01.015

China Mechanical Engineering ›› 2024, Vol. 35 ›› Issue (01): 152-159.DOI: 10.3969/j.issn.1004-132X.2024.01.015

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Experimental Study of Dry Aerosol Jet Printing with Sheath Gas-assisted Aerodynamics Lens Focusing

SHU Xiayun1,2,3;WANG Ce1,2,3;CHANG Xuefeng2,4;ZHONG Zhidong1,2,3;TANG Yiquan1,2,3

1.School of Mechanical & Automation Engineering，Xiamen University of Technology,Xiamen,
Fujian,361024
2.Key Laboratory of Precision Drive and Transmission of Fujian Province University,Xiamen,
Fujian,361024
3.Xiamen Key Laboratory of Intelligent Manufacturing Equipment,Xiamen，Fujian，361024
4.College of Marine Equipment and Mechanical Engineering，Jimei University,Xiamen，Fujian，361021

Online:2024-01-25 Published:2024-02-29

鞘气辅助空气动力学透镜聚焦的干法气溶胶喷印实验研究

舒霞云1,2,3;王策1,2,3;常雪峰2,4;钟智东1,2,3;唐毅泉1,2,3

1.厦门理工学院机械与汽车工程学院，厦门，361024
2.精密驱动与传动福建省高等学校重点实验室，厦门，361024
3.厦门市智能制造高端装备研究重点实验室，厦门，361024
4.集美大学海洋装备与机械工程学院，厦门，361021

作者简介:舒霞云，男，1979年生，博士、副研究员。研究方向为微纳增材制造和有机电子器件制造。E-mail：shuxiayun@xmut.edu.cn。
基金资助:
国家自然科学基金(51975501）；福建省自然科学基金(2022J011243)

Abstract

Abstract: To overcome the most important concerns, such as harsh storage conditions and the removal of solvents and surfactants in aerosol jet printing(AJP) technology, a nano-powder aerosol printing device with sheath gas assisted aerodynamic lens focusing was proposed, and the aerosol jet printing system was established, and the effects of printing speed, volume flow ratio of sheath gas and carrier gas on printing efficiency and line morphology were explored. The effects of laser treatment on the resistivity, microscopic morphology and oxidation degree of aerosol printing lines were analyzed by laser sintering experiments and electrochemical performance test experiments. Experimental results show that when the printing speed is 19.20 mm/min and the volume flow ratio of sheath gas to carrier gas is 2.65, the minimum width of the printing line is 56.52 μm. After laser sintering, the nano silver powder particles in the printing lines melt and agglomerate and form filaments to bond with each other, which significantly reduces the resistivity of the aerosol printing lines.

Key words: dry aerosol jet printing, aerodynamics lens, sheath gas-assisted focusing, jet printing line morphology, laser sintering

摘要： 针对气溶胶喷印技术中油墨存储条件苛刻和溶剂、表面活性剂去除等问题，提出了一种鞘气辅助空气动力学透镜聚焦的纳米粉末气溶胶喷印装置，建立了气溶胶喷印系统，探究了喷印速度、鞘气/载气体积流量比值对系统喷印效率、线条形貌的影响。通过激光烧结实验及电化学性能测试实验，分析了激光处理对气溶胶喷印线条电阻率、微观形貌、氧化程度的影响。实验结果表明：当喷印速度为19.20 mm/min、鞘气/载气体积流量比值为2.65时，获得了最小宽度为56.52 μm的喷印线条；激光处理后，喷印线条中的纳米银粉末颗粒融化团聚并形成丝状物互相黏结，显著降低喷印线条的电阻率。

关键词: 干法气溶胶喷印, 空气动力学透镜, 鞘气辅助聚焦, 喷印线条形貌, 激光烧结

CLC Number:

TS851

SHU Xiayun, WANG Ce, CHANG Xuefeng, ZHONG Zhidong, TANG Yiquan, . Experimental Study of Dry Aerosol Jet Printing with Sheath Gas-assisted Aerodynamics Lens Focusing[J]. China Mechanical Engineering, 2024, 35(01): 152-159.

舒霞云, 王策, 常雪峰, 钟智东, 唐毅泉, . 鞘气辅助空气动力学透镜聚焦的干法气溶胶喷印实验研究[J]. 中国机械工程, 2024, 35(01): 152-159.

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Experimental Study of Dry Aerosol Jet Printing with Sheath Gas-assisted Aerodynamics Lens Focusing

鞘气辅助空气动力学透镜聚焦的干法气溶胶喷印实验研究

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